US20050235938A1 - Valve controller - Google Patents
Valve controller Download PDFInfo
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- US20050235938A1 US20050235938A1 US11/111,780 US11178005A US2005235938A1 US 20050235938 A1 US20050235938 A1 US 20050235938A1 US 11178005 A US11178005 A US 11178005A US 2005235938 A1 US2005235938 A1 US 2005235938A1
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- Prior art keywords
- power source
- driving circuit
- motor
- valve controller
- detected
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
- F01L1/00—Valve-gear or valve arrangements, e.g. lift-valve gear
- F01L1/34—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of means for changing the timing of the valves without changing the duration of opening and without affecting the magnitude of the valve lift
- F01L1/344—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of means for changing the timing of the valves without changing the duration of opening and without affecting the magnitude of the valve lift changing the angular relationship between crankshaft and camshaft, e.g. using helicoidal gear
- F01L1/352—Valve-gear or valve arrangements, e.g. lift-valve gear characterised by the provision of means for changing the timing of the valves without changing the duration of opening and without affecting the magnitude of the valve lift changing the angular relationship between crankshaft and camshaft, e.g. using helicoidal gear using bevel or epicyclic gear
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
- F01L2800/00—Methods of operation using a variable valve timing mechanism
- F01L2800/03—Stopping; Stalling
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01L—CYCLICALLY OPERATING VALVES FOR MACHINES OR ENGINES
- F01L2820/00—Details on specific features characterising valve gear arrangements
- F01L2820/03—Auxiliary actuators
- F01L2820/032—Electric motors
Definitions
- the present invention relates to a valve controller, which adjusts a valve opening/closing character of an internal combustion engine, utilizing a motor torque.
- the internal combustion engine is referred to as an engine hereinafter.
- JP-U-4-105906 shows a valve-timing controller which utilizes a motor torque.
- JP-11-324625A shows a valve lift controller which utilizes a motor torque.
- an electric power source of a driving circuit is turned ON from an engine-start signal is generated until an engine-stop signal is generated, otherwise the electric power source is turned OFF.
- a rotation sensor detects an engine rotation speed to output an engine speed signal, on which a control circuit generates a control signal.
- the driving circuit supplies an electric current to the motor according to the control signal.
- the engine has run by an inertial force thereof for a moment since the engine-stop signal is generated.
- the motor receives no electric current from the electric power source which the driving circuit operates. That is, the driving circuit supplies no electric current to the motor after the engine-stop signal is generated, so that the motor serves a load that generates a deviation in the valve opening/closing character.
- the driving circuit supplies no electric current to the motor after the engine-stop signal is generated, so that the motor serves a load that generates a deviation in the valve opening/closing character.
- the driving circuit cannot supply the electric current to the motor before the engine-starting signal is generated. Thereby, even if the valve opening/closing character is deviated before the engine-start signal is generated, the valve opening/closing character cannot be adjusted to the proper character for starting the engine.
- the rotation sensor detecting the engine rotation speed inherently has a lower-limit in which the rotation sensor can detects the lowest engine rotation speed, so that the rotation sensor outputs no engine speed signal for a moment after the engine is started.
- the control circuit Until the engine speed signal is generated, the control circuit generates no control signal and the driving circuit conducts no activation of the motor.
- the motor serves a load that generates a deviation in the valve opening/closing character, so that it is difficult to realize the proper valve character that is required for starting the engine.
- the present invention is made in view of the foregoing matter and it is an object of the present invention to provide a valve controller capable of realizing the proper valve opening/closing timing according to the engine condition.
- a valve controller of the present invention includes a detecting means for detecting a shutdown command to the internal combustion engine; a driving circuit energizing a motor; and a power source control means for turning on/off a power source of the driving circuit after the detecting means detects the shutdown command.
- FIG. 1 is a flowchart showing an operation of the motor driver according to a first embodiment
- FIG. 2 is a cross sectional view of a valve timing controller according to the first embodiment
- FIG. 3 is a cross sectional view of the valve timing controller taken along the line III-III in FIG. 2 ;
- FIG. 4 is a cross sectional view of the valve timing controller taken along the line IV-IV in FIG. 2 ;
- FIG. 5 is circuit diagram showing an essential part of a current driving part according to the firs embodiment
- FIG. 6 is a block diagram of the motor driver according to the first embodiment
- FIG. 7 is a flowchart showing a failsafe operation of the motor driver according to the first embodiment
- FIG. 8 is a flowchart showing an operation of the motor driver according to a second embodiment
- FIG. 9 is a flowchart showing an operation of the motor driver according to a third embodiment.
- FIG. 10 is a flowchart showing an operation of the motor driver according to a fourth embodiment
- FIG. 11 is a flowchart showing an operation of the motor driver according to a fifth embodiment
- FIG. 12 is a flowchart showing an operation of the motor driver according to a sixth embodiment
- FIG. 13 is a flowchart showing an operation of the motor driver according to a seventh embodiment
- FIG. 14 is a flowchart showing an operation of the motor driver according to an eighth embodiment
- FIG. 15 is a block diagram showing the motor driver according to an eighth embodiment.
- FIG. 16 is a flowchart showing an operation of the motor driver according to a ninth embodiment
- FIG. 17 is a partially cross sectional perspective view of an essential part of the valve lift adjuster according to a tenth embodiment
- FIG. 18 is a perspective view showing an essential part of an actuator according to the tenth embodiment.
- FIG. 19 is a side view showing an essential part pf the actuator according to the tenth embodiment.
- FIG. 20 is a block diagram showing the motor driver according to the tenth embodiment.
- FIG. 21 is a circuit diagram showing a current driving part according to the tenth embodiment.
- valve-timing controller is referred to as VTC hereinafter.
- VTC 10 equipped with an engine of a vehicle changes a valve timing of an intake valve and/or an exhaust valve, which is one of valve opening/closing character, with utilizing a rotational torque of a motor 12 .
- a structure of the motor 12 is described in detail below.
- the motor 12 is a three-phase brushless motor having a motor shaft 14 , bearings 16 , Hall effect elements 18 and a stator 20 .
- the motor shaft 14 is rotationally supported by a pair of bearings 16 around an axis “O” in a normal and reverse direction.
- a clockwise direction of the motor shaft 14 in FIG. 3 is referred to as a normal direction
- counterclockwise direction is referred to as a reverse direction.
- a rotor 15 is provided on the motor shaft 14 and has a plurality of magnets 15 a therein.
- Each of magnets 15 a is disposed at a regular interval around the axis “O” in such a manner that a magnetic pole of the magnet 15 a is opposite to a magnetic pole generated in an outer wall of the rotor 15 .
- Three Hall effect elements are disposed at a vicinity of the rotor 15 .
- Each of the Hall effect elements 18 generates digital signals as detected signals of which voltage is increased or decreased according to whether the position of the magnet 15 a is in a predetermined angle range, the magnet 15 a generating a North pole in the outer wall of the rotor 15 .
- the stator 20 is disposed around the motor shaft 14 .
- the stator 20 has twelve cores 21 which are disposed at regular intervals around the axis “o” and on each of which a coil 22 is wound.
- the coils 22 are connected in the star connection at ends and are connected to a driving circuit 150 of a motor driver 100 at the other ends 23 .
- Each of coils 22 generates a rotational magnetic field around the motor shaft 14 in a clockwise direction or counterclockwise direction.
- a clockwise magnetic field When a clockwise magnetic field is generated, a normal direction torque is applied to the motor shaft 14 , with the magnets 15 a receiving an interactive action in this magnetic field.
- a counterclockwise magnetic field is generated, a reverse direction torque is applied to the motor shaft 14 .
- a phase changing mechanism 30 of the VTC 10 is described hereinafter.
- the phase changing mechanism 30 includes a sprocket 32 , a ring gear 33 , an eccentric shaft 34 , a planetary gear 35 , and an output shaft 36 .
- the sprocket 32 is provided on the same axis of the output shaft 36 , and rotates around the axis “O” in the same direction as the motor shaft 14 .
- a driving torque of the crankshaft of the engine is transferred to the sprocket 32 through a chain belt, the sprocket 32 rotates clockwise around axis “O” in FIG. 4 , keeping a rotational phase relative to the crankshaft. That is, the sprocket 32 functions as a rotating body rotating in synchronization with the crankshaft.
- the ring gear 33 is an internal gear, and is coaxially fixed on the inside of the sprocket 32 to rotate together.
- the eccentric shaft 34 is directly connected to the motor shaft 14 in such a manner that the outer wall is eccentric to the axis “O”.
- the planetary gear 35 is an external gear, and is disposed in the inside of the ring gear 33 while engaging the teeth thereof with the teeth of the ring gear 33 .
- the planetary gear 35 is coaxially supported by the eccentric shaft 34 and rotates around an eccentric axis “Q”.
- the output shaft 36 is coaxially connected to the camshaft 11 by a bolt to rotate around the axis “O” with the camshaft 11 .
- the output shaft 36 has an engaging plate 37 which is a disk-shaped plate having the center axis “O”.
- the engaging plate 37 has a plurality of engaging holes 38 which are formed at regular intervals around the axis “O”.
- the planetary gear 35 has nine engaging projections 39 around the eccentric axis “Q” which are engaged with the engaging holes 38 individually.
- H-level high voltage
- L-level low voltage
- the motor driver 100 includes a control circuit 110 , a first switch 130 , a second switch 140 , and a driving circuit 150 , which are disposed in a proper positions, although FIG. 2 schematically illustrates the motor driver 100 is disposed outside the motor 12 .
- the control circuit 110 includes a main control part 112 and a power source control part 114 .
- the main control part 112 controls ignition timing, a fuel injection and the like of the engine, and generates a command signal which is sent to the power source control part 114 .
- the main control part 112 sets a control target to drive the motor 12 in such a manner that a proper valve timing for the engine condition is conducted.
- the control target is at least one of a target rotational speed of the motor shaft 14 , a target variation amount of the rotational speed of the motor shaft 14 , a rotational direction of the motor shaft 14 , and a load current of the motor 12 .
- the main control part 112 generates digital signals indicative of the control target.
- the single main control signal can indicate the single control target, or a plurality of control targets.
- the main control signal corresponds to a control signal of the present invention.
- the main control part 112 is electrically connected to a first rotation speed sensor 116 to receive a first rotation speed signal indicative of a rotational speed of the crankshaft by its frequency.
- the main control part 112 is electrically connected to a second rotation speed sensor 117 to receive a second rotation speed signal indicative of a rotational speed of the camshaft 11 by its frequency.
- the first and the second rotation speed signal can be digital signals or analog signals.
- the main control part 112 is connected to three Hall effect elements 18 to receive detected signals by the Hall effect elements.
- the power source control part 114 generates command signals for the main control part 112 .
- the power source control part 114 is electrically connected to a switch sensor 118 which detects on-off position of the ignition switch.
- the switch sensor 118 sends a digital signal in H-level with ignition switch on, and sends a digital signal in L-level with ignition switch off.
- the power source control part 114 is electrically connected to a key-sensor 119 which detects whether an ignition key is inserted into a key hole.
- the key-sensor 119 sends a digital signal in H-level with the key inserted, and sends a digital signal in L-level with the key not inserted.
- the power source control part 114 receives electricity from a battery 120 when the signal from the key-sensor 119 is in H-level, or always receives electricity from the battery 120 .
- the power source control part 114 generates a first power source control signal to activate the drive circuit 150 .
- the first power source control signal in H-level turns on the power source of the driving circuit 150
- the first power source control signal in L-level turns off the power source of the driving circuit 150 .
- the power source control part 114 generates a second power source control signal to activate the main control part 112 .
- the second power source signal in H-level turns on the power source of the main control part 112
- the second power source signal in L-level turns off the power source of the main control part 112 .
- the first switch 130 includes an electromagnetic relay having mechanical contacts, and is disposed on an electrical power line 132 connecting the battery 120 and the driving circuit 150 .
- the first switch 130 is connected to the power source control part 114 to receive the first power source control signal generated by the power source control part 114 .
- the first switch 130 is turned on to permit the electric power supply from the battery 120 to the driving circuit 150 , so that the driving circuit 150 is activated.
- the first power source control signal is in L-level, the first switch 130 is turned off to stop the electric power supply from the battery 120 to the driving circuit 150 , so that the driving circuit 150 is deactivated.
- the second switch 140 includes an electromagnetic relay having mechanical contacts, and is disposed on an electrical power line 142 connecting the battery 120 and the main control part 112 .
- the second switch 140 is connected to the power source control part 114 to receive the second power source control signal generated by the power source control part 114 .
- the second switch 140 When the second power source control signal is in H-level, the second switch 140 is turned on to permit the electric power supply from the battery 120 to the main control part 112 , so that the main control part 112 is activated.
- the second switch 140 is turned off to stop the electric power supply from the battery 120 to the main control part 112 , so that the main control part 112 is deactivated.
- the driving circuit 150 comprises a current driving part 152 and a detecting part 154 .
- the current driving part 152 includes a bridge circuit 156 in which each of three arms 155 is connected to terminal 23 of the motor 12 .
- Each one end of the arms 155 is connected to the electrical power line 132 , and the other end is grounded.
- the current driving part 152 is electrically connected to the main control part 112 to receive the main control signal generated by the main control part a 112 .
- the current driving part 152 is connected to three Hall effect elements 18 to receive the detected signals.
- the current driving part 152 establishes switching patterns according to the main control signal and the detected signal, and turns on/off the switching elements 158 a , 158 b according to the switching patterns. Thereby, the motor 12 is activated to realize the control target represented by the main control signal.
- a resistor element 162 is respectively disposed on each arm 155 between the switching element 158 a and a connecting point 161 to which the electrical power line 132 is electrically connected.
- the detecting part 154 is connected to both ends of the resistor element 162 to detect current passing through the resistor element 162 , which is indicative of current condition of the motor 12 .
- the detecting part 154 is electrically connected to the power source control part 114 to generate digital signals indicative of the current passing through the resistor element 162 as a monitor signal to be sent to the power source control part 114 .
- a valve timing in cranking the engine is referred to as a cranking valve timing
- a valve timing right after the engine is started is referred to as an after-start valve timing.
- FIG. 1 is a flowchart showing the operation of the motor driver 100 .
- the power source control part 114 receives H-level signal from the key-sensor 119 to determine that ignition key is inserted to the ignition keyhole in step S 1 .
- the power source control part 114 generates the first power source control signal in H-level and the second power source control signal in H-level in step S 2 , which cause the first and the second switch 130 , 140 to be turned on, so that the driving circuit 150 and the main control part 112 are energized.
- Each power source of the driving circuit 150 and the main control part 112 is maintained on until a process in step S 17 is executed or a failsafe operation is executed.
- step S 3 the energized main control part 112 generates the main control signal until a process in step S 7 is executed.
- the main control part 112 establishes the control target to realize the cranking valve timing based on the detected signals by the Hall effect elements 18 , and then generates the main control signal indicative of the control target.
- the current driving part 152 drives the motor 12 according to the main control signal in step S 4 in such a manner as to bring the rotational phase of the output shaft 36 relative to the sprocket 32 into the cranking valve timing by the phase changing mechanism 30 .
- step S 5 the power source control part 114 receiving the H-level signal from the switch sensor 18 determines that a cranking command is detected in step S 5 .
- step S 6 the power control part 114 generates and sends a command signal to the main control part 112 .
- the main control part 112 starts the ignition and the fuel injection of the engine, and generates the main control signal until a process in step S 10 is executed in step S 7 .
- the main control part 112 establishes the control target to realize the after-start valve timing according to the detected signals by the Hall effect elements 18 , and generates the main control signal indicative of the control target.
- step S 8 the current driving part 152 receiving the main control signal activates the motor 12 based on the main control signal in such a manner as to bring the rotational phase of the output shaft 36 relative to the sprocket 32 into the after-start valve timing by the phase changing mechanism 30 .
- step S 9 after the engine is started, when the rotation speeds of the crankshaft and the camshaft 11 are lowered than the lower limit of the detected signal by the first rotation speed sensor 116 and the second rotation speed sensor 117 ,
- the main control part 112 receives and detects the first rotation speed signal and the second rotation speed signal. At this time, the main control part 112 detects a variation in voltage of the signals from the first rotation speed sensor 116 and the second rotation speed sensor 117 to determine the first and the second rotation speed signal are detected. When both the first and the second rotation speed signal are detected, the main control part 112 generates the main control signal to realize proper valve timing in step S 10 .
- the current driving part 152 drives the motor 12 according to the control signal in step S 11 .
- the rotational phase of the output shaft 36 relative to the sprocket 32 is brought into or kept in a rotational phase to realize proper valve timing by the phase changing mechanism 30 .
- the power source control part 114 receiving the L-level signal from the switch sensor 18 determines that a shutdown command is detected in step S 12 .
- the power control part 114 generates and sends a command signal to the main control part 112 .
- the main control part 112 terminates the ignition and the fuel injection of the engine with the engine running by inertia thereof, and generates the main control signal until a predetermined period T 1 has been elapsed in step S 14 .
- the main control part 112 establishes the control target to realize the cranking valve timing according to the first and the second rotation speed signal or the detected signals by the Hall effect elements 18 , and generates the main control signal indicative of the control target.
- the predetermined period T 1 is longer than the period from the time when the ignition and the fuel injection are terminated to the engine running at a maximum speed to the time when the engine is completely stopped.
- the period T 1 is pre-stored in the main control part 112 .
- the current driving-part 152 receiving the main control signal activates the motor 12 based on the main control signal in such a manner that the rotational phase of the output shaft 36 relative to the sprocket 32 is brought into and kept in the cranking valve timing by the phase changing mechanism 30 .
- the main control part 112 When a predetermined period T 2 has elapsed since the command signal is generated in step S 13 , the main control part 112 generates and sends a command signal to the power source control part in step S 16 .
- the period T 2 is longer than the period T 1 in which current is supplied to the motor 12 based on the main control signal, and is stored in the main control part 112 .
- the power source control part 114 receives the command signal to generate the first and the second power source signal in L-level in step S 17 . This causes the first switch 130 and the second switch 140 to open the contacts 137 , 147 simultaneously, so that the power source of the driving circuit 150 and the main control part 112 are turned off.
- the period T 2 is longer than the period T 1 , the power source of the driving circuit 150 and the main control part 112 is turned off after the process in step S 15 is executed.
- the detecting part 154 When the earth fault is occurred at the connecting points 157 so that an over-current is supplied to the bridge circuit 156 and the coils 22 , the detecting part 154 generates a monitor signal indicative of an abnormality in step S 21 .
- the power source control part 114 receiving the monitor signal determines that the current abnormality is detected based on the monitor signal in step S 22 . Then, the power source control part 114 generates the first power source signal in L-level in step S 23 .
- the first switch 130 opens the contact 137 to turn off the power source of the driving circuit 150 .
- the power source control part 114 keeps the second power source control signal in H-level, which causes the contacts 147 of the second switch 140 to be opened so that the power source of the main control part 112 is kept on.
- the control circuit 110 , the first switch 130 , and the second switch 140 correspond to a power source control means, and the control circuit 110 , the switch sensor 118 and the key-sensor 119 correspond to a detecting means in the present invention.
- the power source of the driving circuit 150 and the main control part 112 are turned on to drive the motor 12 based on the main control signal.
- the valve timing is kept in the cranking valve timing at the time of engine cranking.
- the insert operation of the ignition key prior to the cranking command causes the power source to be turned on, and causes the motor 12 to be energized.
- the period in which the power source is on and the motor 12 is energized before the cranking command is minimized so that electric power consumption is reduced.
- the insert operation of the ignition key causes the first and the second switch 130 , 140 to be operated simultaneously, so that the power source of the driving circuit 150 and the main control part 112 are turned on at the same time. This simplifies the operation of the power source control part 114 .
- the driving circuit 150 and the motor 12 are activated according to the main control signal generated without respect to the rotation speed signal even if the first and the second rotation speed signal have not detected yet. Thereby, during the period from the engine cranking to the detection of the first and the second rotation speed signal, the after-start valve timing is continuously maintained.
- the power source of the driving circuit 150 and the main control part 112 are turned on until the period T 2 has passed.
- the driving circuit 150 drives the motor 12 according to the main control signal from the main control part 112 until the period T 1 has passed, which is shorter than the period T 2 . Since the period T 1 and the period T 2 are longer than the period from the time when the ignition and the fuel injection are terminated to the engine running at a maximum speed to the time when the engine is completely stopped, the valve timing, in which the engine is completely off, is consistent with the cranking valve timing. Thus, the engine can be restarted in the cranking valve timing. Furthermore, since the period T 1 and the period T 2 are pre-stored, it is unnecessary to determine those period.
- the power source control part 114 simultaneously controls the first switch 130 and the second switch 140 , so that the power source of the driving circuit 150 and the main control part 112 are simultaneously turned off to simplify the process by the power source control part 114 .
- the power source of the driving circuit 150 is forcibly turned off to avoid malfunctions of the driving circuit 150 and the motor 12 .
- the power source of the main control part 112 is independently controlled to be on, so that the main control part 112 can control the engine.
- FIG. 8 is a flowchart showing the operation of the motor driver.
- step S 31 to step S 43 are the same processes as step S 1 to step S 13 in FIG. 1 .
- the main control part 112 receiving the command signal generated in step S 43 generates the main control signal with the engine running by inertia thereof until the engine is completely stopped in step S 44 .
- the main control part 112 estimates time t 1 in which the engine is completely stopped according to the first rotation speed and/or the second rotation speed.
- the main control part 112 establishes the control target to realize the cranking valve timing at the time t 1 based on the first and the second rotation speed signal or the detected signal by the Hall effect elements 18 in the case that no rotation speed signal is output.
- the main control signal indicative of the control target is generated.
- the processes in steps S 45 to S 47 which are the same processes as in steps S 15 to S 17 are executed.
- the period T 2 in step S 46 is longer than the period from the time when the ignition and the fuel injection are terminated with respect to the engine running at maximum speed to the time when the engine is completely stopped.
- the valve timing at the time t 1 can be consistent with the cranking valve timing.
- the engine can be re-started in the condition in which the cranking valve timing is established.
- a third embodiment is a modification of the second embodiment.
- FIG. 9 is a flowchart showing an operation of the motor driver.
- step S 51 to step S 65 are the same processes as step S 31 to step S 45 in FIG. 8 .
- step S 66 the main control part 112 generates and sends a command signal to the power source control part 114 at the time t 1 .
- the power source control part 114 receiving the command signal generates the first power source control signal and the second power source control signal in step S 67 .
- the power source of the driving circuit 150 and the main control part 112 are turned of simultaneously.
- the power source of the driving circuit 150 and the main control part 112 are on until the engine is completely stopped, and the driving circuit 150 energizes the motor 12 according to the main control signal from the main control part 112 .
- the valve timing at the time t 1 is consistent with the cranking valve timing.
- the engine can be restarted in a condition in which the cranking valve timing is established.
- the period, in which the power source of the driving circuit 150 and the main control part 112 are on after the shutdown command is generated is consistent with the period in which the motor 12 is energized after the shutdown command is generated.
- FIG. 10 is a flowchart showing an operation of the motor driver.
- step S 71 to step S 83 are the same processes as step S 31 to step S 45 in FIG. 8 .
- step S 84 the main control part 112 receiving the command signal generated in step S 83 generates a main control signal with the engine running by its inertia until the valve timing is brought into be consistent with the target valve timing.
- the main control part 112 estimates the time t 1 , in which the engine is completely stopped, in the same manner as the process in step S 44 .
- the main control part 112 calculates a target valve timing at a time t 2 prior to the time t 1 in such a manner that the cranking valve timing can be established at the time t 1 according to the first rotational speed signal and the second rotational speed signal.
- the main control part 112 generates the main control signal indicative of the control target in which the target valve timing at the time t 2 is established.
- the motor 12 which is deenergized at the time t 2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia. At the time t 1 , the valve timing is brought into be consistent with the cranking valve timing. Thus, the engine can be re-started in the condition in which the cranking valve timing is established.
- a fifth embodiment is a modification of the fourth embodiment.
- FIG. 11 is a flowchart showing an operation of the motor driver.
- step S 91 to step S 105 are the same processes as step S 71 to step S 85 in FIG. 10 .
- the main control part 112 generates and sends the command signal to the power source control part 114 .
- the power source control part 114 generates the first and the second power source control signal in L-level in step S 107 , so that the power source of the driving circuit 150 and the main control part 112 are turned off simultaneously.
- the power source of the driving circuit 150 and the main control part 112 are turned on until the target valve timing is established at the time t 2 in order to energize the motor 12 based on the main control signal even after the shutdown command of the engine is generated.
- the motor 12 which is deenergized at the time t 2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia.
- the valve timing is brought into be consistent with the cranking valve timing.
- the period in which the power source of the driving circuit 150 and the main control part 112 is turned on after the shutdown command is generated is substantially consistent with the period in which the motor 12 is energized after the shutdown command is generated, so that the electric power consumption is reduced.
- FIG. 12 is a flowchart showing an operation of the motor driver.
- step S 111 to step S 125 are the same processes as step S 71 to step S 85 in FIG. 10 .
- step S 126 the main control part 112 generates and sends the command signal to the power source control part 114 at the time t 1 after the time t 2 .
- the power source control part 114 generates the first and the second power source control signal in L-level in step S 107 , so that the power source of the driving circuit 150 and the main control part 112 are turned off simultaneously.
- the power source of the driving circuit 150 and the main control part 112 are turned on until the engine is completely stopped.
- the motor 12 is energized based on the main control signal of the main control part 112 until the target valve timing is established at the time t 2 prior to time t 1 even after the shutdown command of the engine is generated.
- the motor 12 which is deenergized at the time t 2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia. At the time t 1 , the valve timing is brought into be consistent with the cranking valve timing. Thus, the engine can be re-started in the condition in which the cranking valve timing is established.
- a seventh embodiment is a modification of the second embodiment.
- FIG. 13 is a flowchart showing the operation of the motor driver.
- step S 131 to step S 143 are the same processes as step S 31 to step S 45 in FIG. 8 .
- step S 144 the main control part 112 generates the main control signal with the engine running by its inertia until the process in step 147 or step S 148 is executed.
- the main control part 112 estimates the time t 1 and establishes the control target in the same way as the process in step S 44 of the second embodiment.
- the current driving apart 152 receiving the main control signal generated by the main control part 112 energizes the motor 12 based on the main control signal in step S 145 .
- step S 146 the main control part 112 determines whether the valve timing is brought to be consistent with the cranking valve timing prior to the time t 1 .
- the main control part 112 calculates the actual valve timing based on the first rotational speed signal and the second rotational speed signal or on the detected signal by the Hall effect elements 18 . Then, the main control part 112 executes the above determination by comparing the calculated actual valve timing with the pre-stored cranking valve timing.
- the main control part 112 executes the maintaining control in step S 147 .
- the main control signal is generated which is indicative of the control target in order to maintain the cranking valve timing until the time t 1 based on the first rotational speed signal and the second rotational speed signal or on the detected signal by the Hall effect elements 18 in the case that the first and the second rotational speed signal are not generated.
- step S 148 When it determines that the valve timing is consistent with the cranking valve timing prior to the time t 1 , an additional control is executed in step S 148 .
- the control target is additionally established until the valve timing is consistent with the cranking valve timing based on the detected signals by the Hall effect elements, and the main control signal indicative of the control target is generated.
- steps S 149 to S 151 which corresponds to steps S 45 to S 47 in the second embodiment, are executed.
- the motor 12 is energized in such a manner that the valve timing at the time t 1 is consistent with the cranking valve timing even after the engine shutdown command is generated.
- the cranking valve timing may be realized prior to the time t 1 or may not be realized even after the time t 1 due to disturbances.
- the motor 12 is energized until the engine is completely stopped, so that even if the cranking vale timing is realized prior to the time t 1 , the motor 12 is energized so as to maintain the cranking valve timing until the time t 1 . If the cranking valve timing is not realized even at the time t 1 , the motor 12 is energized until the cranking valve timing is realized.
- the engine can be re-started in the condition in which the cranking valve timing is established.
- FIG. 14 is a flowchart showing the operation of the motor driver.
- step S 161 to step S 179 are the same processes as step S 131 to step S 149 in the seventh embodiment.
- step S 180 the main control part 112 generates and sends the command signal to the power source control part 114 when the engine is completely stopped and the valve timing is consistent with the cranking valve timing.
- the power source control part 114 receiving the command signal generates the first and the second power source control signal in L-level in step S 181 , so that the power source of the driving circuit 150 and the main control part 112 are simultaneously turned off.
- the power source of the driving circuit 150 and the main control part 112 are turned on, and the driving circuit 150 energizes the motor 12 according to the main control signal from the main control part 112 .
- the cranking valve timing is maintained in the same manner as the seventh embodiment.
- the engine can be re-started in the condition in which the cranking valve timing is established.
- the period in which the power source of the driving circuit 150 and the main control part 112 are turned on is substantially equal to the period in which the motor 12 is energized after the engine shutdown command is generated, so that electric power consumption is reduced.
- FIG. 15 schematically shows the motor driver according to the ninth embodiment.
- the power source control part 202 of the control circuit 201 is not connected to the key-sensor 119 .
- the power source control part 202 receiving the signal in H-level from the switch sensor 118 determines that the engine start command is detected in step S 191 .
- the power source control part 202 generates and sends the first and the second power source control signal to the main control part 112 .
- the first and the second power source control signal in H-level cause the contacts 137 , 147 of the first and the second switch 130 , 140 to be closed, so that the power source of the driving circuit 150 and the main control part 112 are simultaneously tuned on.
- the power source of the driving circuit 150 and the main control part 113 are maintained on until a process in step S 203 or the failsafe operation is executed.
- the main control part 112 receiving the command signal from the power source control part starts the engine, and generates the main control signal in step S 193 in the same way as step S 7 in the first embodiment. Then, the processes in steps S 194 to S 203 that are the same processes as in steps S 8 to S 17 of the first embodiment are executed.
- the control circuit 110 and the switch sensor 118 correspond to the detecting means in the present invention.
- the power source control part 202 simultaneously controls the first switch 130 and the second switch 140 to turn on the power source of the driving circuit 150 and the main control part 112 , so that the control process by the power source part 202 can be simplified.
- FIGS. 17 to 21 shows a valve lift adjuster according to a tenth embodiment.
- the valve lift adjuster 300 adjusts a maximum value of an intake valve lift, which is one of the valve characters, using a rotational torque of a motor 320 .
- the valve lift adjuster 300 includes an actuator 310 which drive a control axis member 330 in an axial direction thereof, and a lift adjusting mechanism (not shown) which adjusts the maximum valve lift amount according to a position of the control axis member 330 .
- the actuator shown in FIG. 7 comprises the motor 320 , control axis member 330 , a transfer portion 340 , a driving cam 350 (shown in FIG. 19 ), an angle sensor 360 , and a motor driving apparatus 370 .
- the motor 320 is a DC-motor, which comprises a rotor 322 on which a coil is wound, and a permanent magnet 324 which covers an outer surface of the rotor 322 .
- a motor gear 328 is provided at an end of a motor shaft 326 , which rotates with the rotor 322 .
- the control axis member 330 is connected to a supporting flame 341 of the transfer portion 340 at one end thereof, and is connected to a lift adjusting mechanism at the other end thereof.
- the control axis member 330 is crossing substantially perpendicularly to the motor shaft 326 .
- a connecting portion 332 which is one end of the control axis member 330 , is engaged with and connected to a connecting portion 342 of the supporting flame 341 .
- a clip 346 is provided between the connecting portion 332 and the connecting portion 342 to connect both of the connecting portions 332 , 342 .
- the transfer portion 340 comprises the supporting flame 341 which is square box-shaped, and a roller 344 which is rotatably supported by the supporting flame 341 at an opposite side relative to the control axis member 330 .
- a camshaft member 352 of the driving cam 350 is inserted into the inside of the supporting flame 41 .
- the driving cam 350 has a cam surface 353 which is in contact with the roller 344 .
- a cam gear 354 and a cam gear 356 are respectively provided at both ends of the camshaft member 352 .
- the cam gear 354 engages with the motor gear 328 to form a reduction mechanism.
- the cam axis member 352 is disposed in parallel to the motor shat 326 .
- a rotational angle range of the cam gear 354 is restricted is such a manner that two projections (not shown) provided on the gear 354 are brought into contact with engaging members 358 , 359 .
- An angle sensor 360 has a sensor gear 362 which engages with the cam gear 356 .
- the angle sensor 360 detects a rotation angle of a sensor rotation member (not shown) engaging with the sensor 362 with the sensor rotation member and the Hall effect elements.
- the angle sensor 360 sends a detected signal to the motor driver 370 .
- the motor driver 370 energizes the coil of the rotor 322 to drive the motor shaft 326 in normal/reverse direction.
- valve lift adjuster 300 The operation of valve lift adjuster 300 is described hereinafter.
- the torque of the motor 320 is transferred to the driving cam 350 through the motor gear 328 and the cam gear 354 .
- the driving cam 350 rotates, contacting with the roller 344 , the supporting flame 341 reciprocates in an axial direction of the axis member 330 .
- the valve lift adjusting mechanism adjusts the maximum valve lift according to the position of the axis member 330 , which moves along the cam profile of the cam surface 353 of the riving cam 350 .
- the motor driver 370 has the almost same structure as the motor driver 100 of the first embodiment except following structure.
- the same parts and components as those in the motor driver 100 are indicated with the same reference and the same descriptions will not be reiterated.
- the main control part 374 of the control circuit 372 establishes the control target to drive the motor 320 in order to realize the maximum valve lift amount which is suitable to the current engine condition.
- the main control part 374 receives a detected signal from the angle sensor 360 .
- the current driving part 382 of the driving circuit 380 has a bridge circuit 386 which eliminated one row of the arms 155 from the bridge circuit 156 of the first embodiment.
- the current driving part 382 receives a detected signal from the angle sensor 360 which is connected thereto.
- the current driving part 382 establishes a switching pattern and turns on/off the switching elements 158 a , 158 b according to the switching pattern to energize the motor 320 , so that the control target represented by the main control signal is realized.
- the motor driver 370 conducts almost the same operation as the first embodiment.
- the main control part 374 establishes the control target based on the detected signal by the angle sensor 360 in order to realize the cranking valve lift that is a maximum valve lift required at the engine starting in step corresponding to step S 3 of the first embodiment.
- the current driving part 382 executes step corresponding to step S 4 , so that the maximum valve lift amount is consistent with the cranking valve lift amount.
- step corresponding to step S 7 the main control part 374 establishes the control target based on the detected signal by the angle sensor 360 in order to realize the after-start valve lift amount which is the maximum valve lift amount required after the engine is turned on.
- the current driving part 382 executes step corresponding to step S 8 to cause the maximum valve lift amount to be consistent with the after-start valve lift amount.
- step corresponding to step S 10 the main control part 374 establishes the control target based on the first and the second rotational speed signal in order to realize the suitable maximum valve lift amount.
- the current driving part 382 executes step corresponding to step S 11 to hold or change the maximum valve lift amount to the suitable amount for the engine.
- step corresponding to step S 14 the main control part 374 established the control target to realize the cranking valve lift amount based on the first and the second rotational speed signal or a detected signal by the angle sensor 360 in the case that the rotational speed signals are not generated.
- the current driving part 382 executes step corresponding to step S 15 , whereby the maximum valve lift is brought into be consistent with the cranking valve lift amount and be kept.
- the motor driver 370 conducts the same failsafe operation as the first embodiment.
- control circuit 372 the first switch 130 , and the second switch 140 correspond to a power source control means.
- the control circuit 372 , the switch sensor 118 and the key-sensor 119 correspond to a detecting means of the present invention.
- the power source of the driving circuit 380 and the main control circuit 374 are turned on to energize the motor 320 .
- the maximum valve lift amount is kept in the cranking valve lift amount, so that the cranking valve lift amount is realized at the time of stating the engine.
- the driving circuit 380 When the engine-start command is detected, the driving circuit 380 energizes the motor 320 according to the main control signal which is generated without respect to the first and the second rotational speed signal even before the first and the second rotational speed signal are generated. Thereby, the after-start valve lift amount is continuously maintained until the first and the second rotational speed signal are detected.
- the power source of the driving circuit 380 and the main control part 374 are turned on until the period T 2 has passed in order to drive the motor 320 until the period T 1 has passed.
- the maximum valve lift amount can be consistent with the cranking valve lift amount at the time when the engine is completely stopped, so that the engine can be re-started in the condition in which the cranking valve lift amount is established.
- the failsafe operation is executed to turn off the power source of the driving circuit 380 , so that the malfunction of the driving circuit 380 and the motor 320 can be avoided.
- the non-contact relay comprised of a semiconductor circuit can be used as the first and the second switch 130 , 140 .
- No failsafe operation can be executed.
- the power source control part 114 can generate the fist and the second power source signal in H-level to turn on the power source of the driving circuit 150 and the main control part 112 based on a braking operation by a driver, an operation of fastening a seatbelt, or stepping operation of a clutch by the driver instead of the insert operation of the ignition key.
- a sensor detecting the operation above is connected to the power source part 114 , 202 to send the detected signal thereto.
- the power sources of the main control part 114 , 202 and the driving circuit 150 , 380 can be respectively independently controlled so that the on-off timing of each power source can be deviated.
- the power source control part 202 before the engine start command is generated, that is, before step S 191 , the power source control part 202 can generates the first power source control signal in L-level and the second power source signal in H-level, so that the power source of the main control part 112 can be turned on prior to the power source of the driving circuit 150 .
- the engine can be replaced by a hybrid engine.
- the three-phase motor can be replaced by the other known motor.
- step S 12 to step S 17 can be skipped.
- step S 192 , step S 193 , and step S 194 can be skipped.
- the motor 12 is energized when the rotational speed of the crankshaft and the camshaft become under the lowest value detected by the first and the second rotational speed sensor 116 , 117 .
- step S 198 to step S 203 can be replaced by steps S 42 to S 47 of the second embodiment, steps S 62 to S 67 of the third embodiment, steps S 82 to S 87 of the fourth embodiment, steps S 102 to S 107 of the fifth embodiment, steps S 122 to S 127 of the sixth embodiment, steps S 142 to S 181 of the seventh embodiment, or steps S 172 to S 181 to the eighth embodiment. Furthermore, steps S 198 to S 203 can be skipped.
- the valve lift amount can be adjusted with respect to the exhaust valve. Steps corresponding to steps S 12 to S 17 can be skipped.
- the normal operation that is same as in the second to ninth embodiments can be executed by the motor driver 370 .
- the main control part 374 establishes the control target to realize the cranking valve lift amount at the time t 1 in step corresponding to step S 44 or step S 64 .
- the main control part 374 calculates the control target in such a manner that the cranking valve lift amount is realized at the time t 1 .
- the main control part 374 when the operation corresponding to that of the seventh or eighth embodiment is executed, the main control part 374 establishes the control target, and determines whether the maximum valve lift amount is consistent with the cranking valve lift amount in step corresponding to step S 146 or S 176 . In the tenth embodiment, the operation corresponding to that of the seventh or eighth embodiment is executed, the main control part 374 establishes the control target in step corresponding to step S 147 or S 177 , and in step corresponding to S 148 or S 178 the main control part 374 establishes the control target. In the tenth embodiment, when the operation corresponding to that of the eighth embodiment is executed, the main control part 374 generates and sends the command signal to the power control part 114 .
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- Engineering & Computer Science (AREA)
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- General Engineering & Computer Science (AREA)
- Output Control And Ontrol Of Special Type Engine (AREA)
- Valve Device For Special Equipments (AREA)
Abstract
Description
- This application is based on and incorporates herein by reference Japanese Patent Application No. 2004-128268 filed on Apr. 23, 2004, the disclosure of which is incorporated herein by reference.
- The present invention relates to a valve controller, which adjusts a valve opening/closing character of an internal combustion engine, utilizing a motor torque. The internal combustion engine is referred to as an engine hereinafter.
- JP-U-4-105906 shows a valve-timing controller which utilizes a motor torque. JP-11-324625A shows a valve lift controller which utilizes a motor torque. In these controllers, an electric power source of a driving circuit is turned ON from an engine-start signal is generated until an engine-stop signal is generated, otherwise the electric power source is turned OFF. A rotation sensor detects an engine rotation speed to output an engine speed signal, on which a control circuit generates a control signal. The driving circuit supplies an electric current to the motor according to the control signal.
- The engine has run by an inertial force thereof for a moment since the engine-stop signal is generated. At this time, the motor receives no electric current from the electric power source which the driving circuit operates. That is, the driving circuit supplies no electric current to the motor after the engine-stop signal is generated, so that the motor serves a load that generates a deviation in the valve opening/closing character. Thus, it is difficult to realize a proper valve character which is required for starting the engine.
- As described above, the driving circuit cannot supply the electric current to the motor before the engine-starting signal is generated. Thereby, even if the valve opening/closing character is deviated before the engine-start signal is generated, the valve opening/closing character cannot be adjusted to the proper character for starting the engine.
- The rotation sensor detecting the engine rotation speed inherently has a lower-limit in which the rotation sensor can detects the lowest engine rotation speed, so that the rotation sensor outputs no engine speed signal for a moment after the engine is started. Until the engine speed signal is generated, the control circuit generates no control signal and the driving circuit conducts no activation of the motor. Thus, the motor serves a load that generates a deviation in the valve opening/closing character, so that it is difficult to realize the proper valve character that is required for starting the engine.
- The present invention is made in view of the foregoing matter and it is an object of the present invention to provide a valve controller capable of realizing the proper valve opening/closing timing according to the engine condition.
- A valve controller of the present invention includes a detecting means for detecting a shutdown command to the internal combustion engine; a driving circuit energizing a motor; and a power source control means for turning on/off a power source of the driving circuit after the detecting means detects the shutdown command.
- The above and other objects, features, and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings, in which like parts are designated by like reference number and in which:
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FIG. 1 is a flowchart showing an operation of the motor driver according to a first embodiment; -
FIG. 2 is a cross sectional view of a valve timing controller according to the first embodiment; -
FIG. 3 is a cross sectional view of the valve timing controller taken along the line III-III inFIG. 2 ; -
FIG. 4 is a cross sectional view of the valve timing controller taken along the line IV-IV inFIG. 2 ; -
FIG. 5 is circuit diagram showing an essential part of a current driving part according to the firs embodiment; -
FIG. 6 is a block diagram of the motor driver according to the first embodiment; -
FIG. 7 is a flowchart showing a failsafe operation of the motor driver according to the first embodiment; -
FIG. 8 is a flowchart showing an operation of the motor driver according to a second embodiment; -
FIG. 9 is a flowchart showing an operation of the motor driver according to a third embodiment; -
FIG. 10 is a flowchart showing an operation of the motor driver according to a fourth embodiment; -
FIG. 11 is a flowchart showing an operation of the motor driver according to a fifth embodiment; -
FIG. 12 is a flowchart showing an operation of the motor driver according to a sixth embodiment; -
FIG. 13 is a flowchart showing an operation of the motor driver according to a seventh embodiment; -
FIG. 14 is a flowchart showing an operation of the motor driver according to an eighth embodiment; -
FIG. 15 is a block diagram showing the motor driver according to an eighth embodiment; -
FIG. 16 is a flowchart showing an operation of the motor driver according to a ninth embodiment; -
FIG. 17 is a partially cross sectional perspective view of an essential part of the valve lift adjuster according to a tenth embodiment; -
FIG. 18 is a perspective view showing an essential part of an actuator according to the tenth embodiment; -
FIG. 19 is a side view showing an essential part pf the actuator according to the tenth embodiment; -
FIG. 20 is a block diagram showing the motor driver according to the tenth embodiment; and -
FIG. 21 is a circuit diagram showing a current driving part according to the tenth embodiment. - An embodiment of the present invention will be described hereinafter with reference to the drawings.
- Referring to FIGS. 2 to 4, a first embodiment, which is applied to a valve-timing controller, is described hereinafter. The valve-timing controller is referred to as VTC hereinafter. The VTC 10 equipped with an engine of a vehicle changes a valve timing of an intake valve and/or an exhaust valve, which is one of valve opening/closing character, with utilizing a rotational torque of a
motor 12. - A structure of the
motor 12 is described in detail below. - As shown in
FIGS. 2 and 3 , themotor 12 is a three-phase brushless motor having amotor shaft 14,bearings 16,Hall effect elements 18 and astator 20. Themotor shaft 14 is rotationally supported by a pair ofbearings 16 around an axis “O” in a normal and reverse direction. In the present embodiment, a clockwise direction of themotor shaft 14 inFIG. 3 is referred to as a normal direction, and counterclockwise direction is referred to as a reverse direction. Arotor 15 is provided on themotor shaft 14 and has a plurality ofmagnets 15 a therein. Each ofmagnets 15 a is disposed at a regular interval around the axis “O” in such a manner that a magnetic pole of themagnet 15 a is opposite to a magnetic pole generated in an outer wall of therotor 15. Three Hall effect elements are disposed at a vicinity of therotor 15. Each of theHall effect elements 18 generates digital signals as detected signals of which voltage is increased or decreased according to whether the position of themagnet 15 a is in a predetermined angle range, themagnet 15 a generating a North pole in the outer wall of therotor 15. - The
stator 20 is disposed around themotor shaft 14. Thestator 20 has twelvecores 21 which are disposed at regular intervals around the axis “o” and on each of which acoil 22 is wound. As shown inFIG. 5 , thecoils 22 are connected in the star connection at ends and are connected to adriving circuit 150 of amotor driver 100 at theother ends 23. Each ofcoils 22 generates a rotational magnetic field around themotor shaft 14 in a clockwise direction or counterclockwise direction. When a clockwise magnetic field is generated, a normal direction torque is applied to themotor shaft 14, with themagnets 15 a receiving an interactive action in this magnetic field. Similarly, when a counterclockwise magnetic field is generated, a reverse direction torque is applied to themotor shaft 14. - A
phase changing mechanism 30 of theVTC 10 is described hereinafter. - As shown in
FIGS. 2 and 4 , thephase changing mechanism 30 includes asprocket 32, aring gear 33, aneccentric shaft 34, aplanetary gear 35, and anoutput shaft 36. - The
sprocket 32 is provided on the same axis of theoutput shaft 36, and rotates around the axis “O” in the same direction as themotor shaft 14. When a driving torque of the crankshaft of the engine is transferred to thesprocket 32 through a chain belt, thesprocket 32 rotates clockwise around axis “O” inFIG. 4 , keeping a rotational phase relative to the crankshaft. That is, thesprocket 32 functions as a rotating body rotating in synchronization with the crankshaft. Thering gear 33 is an internal gear, and is coaxially fixed on the inside of thesprocket 32 to rotate together. - The
eccentric shaft 34 is directly connected to themotor shaft 14 in such a manner that the outer wall is eccentric to the axis “O”. Theplanetary gear 35 is an external gear, and is disposed in the inside of thering gear 33 while engaging the teeth thereof with the teeth of thering gear 33. Theplanetary gear 35 is coaxially supported by theeccentric shaft 34 and rotates around an eccentric axis “Q”. Theoutput shaft 36 is coaxially connected to thecamshaft 11 by a bolt to rotate around the axis “O” with thecamshaft 11. Theoutput shaft 36 has an engagingplate 37 which is a disk-shaped plate having the center axis “O”. The engagingplate 37 has a plurality of engagingholes 38 which are formed at regular intervals around the axis “O”. Theplanetary gear 35 has nineengaging projections 39 around the eccentric axis “Q” which are engaged with the engagingholes 38 individually. - When the
motor shaft 14 does not rotate relative to thesprocket 32, theplanetary gear 35 rotates clockwise inFIG. 4 with thesprocket 32 while maintaining the engaging position with thering gear 33. Because the engagingprojections 39 urge the inner surface of the engagingholes 38, theoutput shaft 36 rotates clockwise without relative rotation to thesprocket 32 by which a rotational phase of thecamshaft 11 relative to the crankshaft is maintained. - When the
motor shaft 14 rotates counterclockwise relative to thesprocket 32, theplanetary gear 35 rotates clockwise relative to theeccentric shaft 34 to change engaging position with thering gear 33. At this moment, the urging force by which the engagingprojections 39 urge the inner surface of the engagingholes 38 increases, so that the rotational phase of theoutput shaft 36 is advanced relative to thesprocket 32. That is, the rotational phase of thecamshaft 11 relative to the crankshaft is advanced and the valve timing is advanced. - When the
motor shaft 14 rotates clockwise relative to thesprocket 32, theplanetary gear 35 rotates counterclockwise relative to theeccentric shaft 34 to change engaging position with thering gear 33. At this moment, the urging force by which the engagingprojections 39 counterclockwise urge the inner surface of the engagingholes 38 increases, so that the rotational phase of theoutput shaft 36 is retarded relative to thesprocket 32. That is, the rotational phase of thecamshaft 11 relative to the crankshaft is retarded and the valve timing is retarded. - A structure of the
motor driver 100 of theVTC 10 is described hereinafter. With respect to voltage of digital signals, the high voltage is referred to as H-level, and the low voltage is refereed to as L-level hereinafter. - As shown in
FIG. 6 , themotor driver 100 includes acontrol circuit 110, afirst switch 130, asecond switch 140, and adriving circuit 150, which are disposed in a proper positions, althoughFIG. 2 schematically illustrates themotor driver 100 is disposed outside themotor 12. - The
control circuit 110 includes amain control part 112 and a powersource control part 114. Themain control part 112 controls ignition timing, a fuel injection and the like of the engine, and generates a command signal which is sent to the powersource control part 114. Themain control part 112 sets a control target to drive themotor 12 in such a manner that a proper valve timing for the engine condition is conducted. The control target is at least one of a target rotational speed of themotor shaft 14, a target variation amount of the rotational speed of themotor shaft 14, a rotational direction of themotor shaft 14, and a load current of themotor 12. Themain control part 112 generates digital signals indicative of the control target. The single main control signal can indicate the single control target, or a plurality of control targets. The main control signal corresponds to a control signal of the present invention. - The
main control part 112 is electrically connected to a firstrotation speed sensor 116 to receive a first rotation speed signal indicative of a rotational speed of the crankshaft by its frequency. Themain control part 112 is electrically connected to a secondrotation speed sensor 117 to receive a second rotation speed signal indicative of a rotational speed of thecamshaft 11 by its frequency. The first and the second rotation speed signal can be digital signals or analog signals. Themain control part 112 is connected to threeHall effect elements 18 to receive detected signals by the Hall effect elements. - The power
source control part 114 generates command signals for themain control part 112. The powersource control part 114 is electrically connected to aswitch sensor 118 which detects on-off position of the ignition switch. Theswitch sensor 118 sends a digital signal in H-level with ignition switch on, and sends a digital signal in L-level with ignition switch off. The powersource control part 114 is electrically connected to a key-sensor 119 which detects whether an ignition key is inserted into a key hole. The key-sensor 119 sends a digital signal in H-level with the key inserted, and sends a digital signal in L-level with the key not inserted. The powersource control part 114 receives electricity from abattery 120 when the signal from the key-sensor 119 is in H-level, or always receives electricity from thebattery 120. - The power
source control part 114 generates a first power source control signal to activate thedrive circuit 150. The first power source control signal in H-level turns on the power source of the drivingcircuit 150, and the first power source control signal in L-level turns off the power source of the drivingcircuit 150. The powersource control part 114 generates a second power source control signal to activate themain control part 112. The second power source signal in H-level turns on the power source of themain control part 112, and the second power source signal in L-level turns off the power source of themain control part 112. - The
first switch 130 includes an electromagnetic relay having mechanical contacts, and is disposed on anelectrical power line 132 connecting thebattery 120 and the drivingcircuit 150. Thefirst switch 130 is connected to the powersource control part 114 to receive the first power source control signal generated by the powersource control part 114. When the first power source control signal is in H-level, thefirst switch 130 is turned on to permit the electric power supply from thebattery 120 to thedriving circuit 150, so that the drivingcircuit 150 is activated. When the first power source control signal is in L-level, thefirst switch 130 is turned off to stop the electric power supply from thebattery 120 to thedriving circuit 150, so that the drivingcircuit 150 is deactivated. - The
second switch 140 includes an electromagnetic relay having mechanical contacts, and is disposed on anelectrical power line 142 connecting thebattery 120 and themain control part 112. Thesecond switch 140 is connected to the powersource control part 114 to receive the second power source control signal generated by the powersource control part 114. When the second power source control signal is in H-level, thesecond switch 140 is turned on to permit the electric power supply from thebattery 120 to themain control part 112, so that themain control part 112 is activated. When the second power source control signal is in L-level, thesecond switch 140 is turned off to stop the electric power supply from thebattery 120 to themain control part 112, so that themain control part 112 is deactivated. - The driving
circuit 150 comprises acurrent driving part 152 and a detectingpart 154. - As shown in
FIG. 5 , thecurrent driving part 152 includes abridge circuit 156 in which each of threearms 155 is connected toterminal 23 of themotor 12. Each one end of thearms 155 is connected to theelectrical power line 132, and the other end is grounded. There are provided two switchingelements arm 155 in such a manner that two switchingelements point 157 in which thearm 155 is connected to theterminal 23 of themotor 12. - As shown in
FIG. 6 , thecurrent driving part 152 is electrically connected to themain control part 112 to receive the main control signal generated by the main control part a 112. Thecurrent driving part 152 is connected to threeHall effect elements 18 to receive the detected signals. Thecurrent driving part 152 establishes switching patterns according to the main control signal and the detected signal, and turns on/off the switchingelements motor 12 is activated to realize the control target represented by the main control signal. - A
resistor element 162 is respectively disposed on eacharm 155 between the switchingelement 158 a and a connectingpoint 161 to which theelectrical power line 132 is electrically connected. - The detecting
part 154 is connected to both ends of theresistor element 162 to detect current passing through theresistor element 162, which is indicative of current condition of themotor 12. The detectingpart 154 is electrically connected to the powersource control part 114 to generate digital signals indicative of the current passing through theresistor element 162 as a monitor signal to be sent to the powersource control part 114. - The operation of the
motor driver 100 is described hereinafter. A valve timing in cranking the engine is referred to as a cranking valve timing, and a valve timing right after the engine is started is referred to as an after-start valve timing. -
FIG. 1 is a flowchart showing the operation of themotor driver 100. When the ignition key is inserted into the ignition keyhole while the engine is off, the powersource control part 114 receives H-level signal from the key-sensor 119 to determine that ignition key is inserted to the ignition keyhole in step S1. The powersource control part 114 generates the first power source control signal in H-level and the second power source control signal in H-level in step S2, which cause the first and thesecond switch circuit 150 and themain control part 112 are energized. Each power source of the drivingcircuit 150 and themain control part 112 is maintained on until a process in step S17 is executed or a failsafe operation is executed. - In step S3, the energized
main control part 112 generates the main control signal until a process in step S7 is executed. Themain control part 112 establishes the control target to realize the cranking valve timing based on the detected signals by theHall effect elements 18, and then generates the main control signal indicative of the control target. Thecurrent driving part 152 drives themotor 12 according to the main control signal in step S4 in such a manner as to bring the rotational phase of theoutput shaft 36 relative to thesprocket 32 into the cranking valve timing by thephase changing mechanism 30. - When the ignition is turned on, the power
source control part 114 receiving the H-level signal from theswitch sensor 18 determines that a cranking command is detected in step S5. In step S6, thepower control part 114 generates and sends a command signal to themain control part 112. Themain control part 112 starts the ignition and the fuel injection of the engine, and generates the main control signal until a process in step S10 is executed in step S7. At the same time, themain control part 112 establishes the control target to realize the after-start valve timing according to the detected signals by theHall effect elements 18, and generates the main control signal indicative of the control target. In step S8, thecurrent driving part 152 receiving the main control signal activates themotor 12 based on the main control signal in such a manner as to bring the rotational phase of theoutput shaft 36 relative to thesprocket 32 into the after-start valve timing by thephase changing mechanism 30. - In step S9, after the engine is started, when the rotation speeds of the crankshaft and the
camshaft 11 are lowered than the lower limit of the detected signal by the firstrotation speed sensor 116 and the secondrotation speed sensor 117, Themain control part 112 receives and detects the first rotation speed signal and the second rotation speed signal. At this time, themain control part 112 detects a variation in voltage of the signals from the firstrotation speed sensor 116 and the secondrotation speed sensor 117 to determine the first and the second rotation speed signal are detected. When both the first and the second rotation speed signal are detected, themain control part 112 generates the main control signal to realize proper valve timing in step S10. Thecurrent driving part 152 drives themotor 12 according to the control signal in step S11. The rotational phase of theoutput shaft 36 relative to thesprocket 32 is brought into or kept in a rotational phase to realize proper valve timing by thephase changing mechanism 30. - When the ignition is turned off, the power
source control part 114 receiving the L-level signal from theswitch sensor 18 determines that a shutdown command is detected in step S12. In step S13, thepower control part 114 generates and sends a command signal to themain control part 112. Themain control part 112 terminates the ignition and the fuel injection of the engine with the engine running by inertia thereof, and generates the main control signal until a predetermined period T1 has been elapsed in step S14. At the same time, themain control part 112 establishes the control target to realize the cranking valve timing according to the first and the second rotation speed signal or the detected signals by theHall effect elements 18, and generates the main control signal indicative of the control target. The predetermined period T1 is longer than the period from the time when the ignition and the fuel injection are terminated to the engine running at a maximum speed to the time when the engine is completely stopped. The period T1 is pre-stored in themain control part 112. In step S15, until the period T1 has passed, the current driving-part 152 receiving the main control signal activates themotor 12 based on the main control signal in such a manner that the rotational phase of theoutput shaft 36 relative to thesprocket 32 is brought into and kept in the cranking valve timing by thephase changing mechanism 30. - When a predetermined period T2 has elapsed since the command signal is generated in step S13, the
main control part 112 generates and sends a command signal to the power source control part in step S16. The period T2 is longer than the period T1 in which current is supplied to themotor 12 based on the main control signal, and is stored in themain control part 112. The powersource control part 114 receives the command signal to generate the first and the second power source signal in L-level in step S17. This causes thefirst switch 130 and thesecond switch 140 to open thecontacts circuit 150 and themain control part 112 are turned off. According the present embodiment, since the period T2 is longer than the period T1, the power source of the drivingcircuit 150 and themain control part 112 is turned off after the process in step S15 is executed. - Referring to a flowchart shown in
FIG. 7 , a fail-safe operation of themotor driver 100 is described hereinafter. - When the earth fault is occurred at the connecting
points 157 so that an over-current is supplied to thebridge circuit 156 and thecoils 22, the detectingpart 154 generates a monitor signal indicative of an abnormality in step S21. The powersource control part 114 receiving the monitor signal determines that the current abnormality is detected based on the monitor signal in step S22. Then, the powersource control part 114 generates the first power source signal in L-level in step S23. Thefirst switch 130 opens thecontact 137 to turn off the power source of the drivingcircuit 150. According to this embodiment, the powersource control part 114 keeps the second power source control signal in H-level, which causes thecontacts 147 of thesecond switch 140 to be opened so that the power source of themain control part 112 is kept on. - The
control circuit 110, thefirst switch 130, and thesecond switch 140 correspond to a power source control means, and thecontrol circuit 110, theswitch sensor 118 and the key-sensor 119 correspond to a detecting means in the present invention. - According to the first embodiment, when the insert operation of the ignition key is detected before the cranking of the engine, the power source of the driving
circuit 150 and themain control part 112 are turned on to drive themotor 12 based on the main control signal. Thereby, the valve timing is kept in the cranking valve timing at the time of engine cranking. The insert operation of the ignition key prior to the cranking command causes the power source to be turned on, and causes themotor 12 to be energized. Thereby, the period in which the power source is on and themotor 12 is energized before the cranking command is minimized so that electric power consumption is reduced. The insert operation of the ignition key causes the first and thesecond switch circuit 150 and themain control part 112 are turned on at the same time. This simplifies the operation of the powersource control part 114. - When the cranking command is detected, the driving
circuit 150 and themotor 12 are activated according to the main control signal generated without respect to the rotation speed signal even if the first and the second rotation speed signal have not detected yet. Thereby, during the period from the engine cranking to the detection of the first and the second rotation speed signal, the after-start valve timing is continuously maintained. - According to the first embodiment, when the engine shutdown command is detected, the power source of the driving
circuit 150 and themain control part 112 are turned on until the period T2 has passed. The drivingcircuit 150 drives themotor 12 according to the main control signal from themain control part 112 until the period T1 has passed, which is shorter than the period T2. Since the period T1 and the period T2 are longer than the period from the time when the ignition and the fuel injection are terminated to the engine running at a maximum speed to the time when the engine is completely stopped, the valve timing, in which the engine is completely off, is consistent with the cranking valve timing. Thus, the engine can be restarted in the cranking valve timing. Furthermore, since the period T1 and the period T2 are pre-stored, it is unnecessary to determine those period. The powersource control part 114 simultaneously controls thefirst switch 130 and thesecond switch 140, so that the power source of the drivingcircuit 150 and themain control part 112 are simultaneously turned off to simplify the process by the powersource control part 114. - When the over-current is supplied to the
driving circuit 150 and themotor 12, the power source of the drivingcircuit 150 is forcibly turned off to avoid malfunctions of the drivingcircuit 150 and themotor 12. The power source of themain control part 112 is independently controlled to be on, so that themain control part 112 can control the engine. - A second embodiment is a modification of the first embodiment.
FIG. 8 is a flowchart showing the operation of the motor driver. InFIG. 8 , step S31 to step S43 are the same processes as step S1 to step S13 inFIG. 1 . Themain control part 112 receiving the command signal generated in step S43 generates the main control signal with the engine running by inertia thereof until the engine is completely stopped in step S44. At this moment, themain control part 112 estimates time t1 in which the engine is completely stopped according to the first rotation speed and/or the second rotation speed. Then, themain control part 112 establishes the control target to realize the cranking valve timing at the time t1 based on the first and the second rotation speed signal or the detected signal by theHall effect elements 18 in the case that no rotation speed signal is output. The main control signal indicative of the control target is generated. After the execution of the process in step S44, the processes in steps S45 to S47 which are the same processes as in steps S15 to S17 are executed. The period T2 in step S46 is longer than the period from the time when the ignition and the fuel injection are terminated with respect to the engine running at maximum speed to the time when the engine is completely stopped. - According to the second embodiment, since the motor 1 is energized even after the engine shutdown command is generated, the valve timing at the time t1 can be consistent with the cranking valve timing. The engine can be re-started in the condition in which the cranking valve timing is established.
- A third embodiment is a modification of the second embodiment.
FIG. 9 is a flowchart showing an operation of the motor driver. - In
FIG. 9 , step S51 to step S65 are the same processes as step S31 to step S45 inFIG. 8 . In step S66, themain control part 112 generates and sends a command signal to the powersource control part 114 at the time t1. The powersource control part 114 receiving the command signal generates the first power source control signal and the second power source control signal in step S67. The power source of the drivingcircuit 150 and themain control part 112 are turned of simultaneously. - According to the third embodiment, the power source of the driving
circuit 150 and themain control part 112 are on until the engine is completely stopped, and the drivingcircuit 150 energizes themotor 12 according to the main control signal from themain control part 112. Thereby, the valve timing at the time t1 is consistent with the cranking valve timing. The engine can be restarted in a condition in which the cranking valve timing is established. Furthermore, the period, in which the power source of the drivingcircuit 150 and themain control part 112 are on after the shutdown command is generated, is consistent with the period in which themotor 12 is energized after the shutdown command is generated. - A fourth embodiment is a modification of the second embodiment.
FIG. 10 is a flowchart showing an operation of the motor driver. - In
FIG. 10 , step S71 to step S83 are the same processes as step S31 to step S45 inFIG. 8 . In step S84, themain control part 112 receiving the command signal generated in step S83 generates a main control signal with the engine running by its inertia until the valve timing is brought into be consistent with the target valve timing. Themain control part 112 estimates the time t1, in which the engine is completely stopped, in the same manner as the process in step S44. Themain control part 112 calculates a target valve timing at a time t2 prior to the time t1 in such a manner that the cranking valve timing can be established at the time t1 according to the first rotational speed signal and the second rotational speed signal. Themain control part 112 generates the main control signal indicative of the control target in which the target valve timing at the time t2 is established. After the execution of the process in step S84, the processes in steps S45 to S47 that are the same process as in steps S15 to S17 are executed. - According to the fourth embodiment, the
motor 12, which is deenergized at the time t2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia. At the time t1, the valve timing is brought into be consistent with the cranking valve timing. Thus, the engine can be re-started in the condition in which the cranking valve timing is established. - A fifth embodiment is a modification of the fourth embodiment.
FIG. 11 is a flowchart showing an operation of the motor driver. - In
FIG. 11 , step S91 to step S105 are the same processes as step S71 to step S85 inFIG. 10 . In step S106, themain control part 112 generates and sends the command signal to the powersource control part 114. The powersource control part 114 generates the first and the second power source control signal in L-level in step S107, so that the power source of the drivingcircuit 150 and themain control part 112 are turned off simultaneously. - According to the fifth embodiment, the power source of the driving
circuit 150 and themain control part 112 are turned on until the target valve timing is established at the time t2 in order to energize themotor 12 based on the main control signal even after the shutdown command of the engine is generated. Themotor 12, which is deenergized at the time t2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia. At the time t1, the valve timing is brought into be consistent with the cranking valve timing. Thus, the engine can be re-started in the condition in which the cranking valve timing is established. The period in which the power source of the drivingcircuit 150 and themain control part 112 is turned on after the shutdown command is generated is substantially consistent with the period in which themotor 12 is energized after the shutdown command is generated, so that the electric power consumption is reduced. - A sixth embodiment is a modification of the fourth embodiment.
FIG. 12 is a flowchart showing an operation of the motor driver. - In
FIG. 12 , step S111 to step S125 are the same processes as step S71 to step S85 inFIG. 10 . In step S126, themain control part 112 generates and sends the command signal to the powersource control part 114 at the time t1 after the time t2. The powersource control part 114 generates the first and the second power source control signal in L-level in step S107, so that the power source of the drivingcircuit 150 and themain control part 112 are turned off simultaneously. - According to the sixth embodiment, the power source of the driving
circuit 150 and themain control part 112 are turned on until the engine is completely stopped. Themotor 12 is energized based on the main control signal of themain control part 112 until the target valve timing is established at the time t2 prior to time t1 even after the shutdown command of the engine is generated. Themotor 12, which is deenergized at the time t2 after the shutdown command is generated, serves as a load which varies the valve timing of the engine running by its inertia. At the time t1, the valve timing is brought into be consistent with the cranking valve timing. Thus, the engine can be re-started in the condition in which the cranking valve timing is established. - A seventh embodiment is a modification of the second embodiment.
FIG. 13 is a flowchart showing the operation of the motor driver. - In
FIG. 13 , step S131 to step S143 are the same processes as step S31 to step S45 inFIG. 8 . In step S144, themain control part 112 generates the main control signal with the engine running by its inertia until the process instep 147 or step S148 is executed. Themain control part 112 estimates the time t1 and establishes the control target in the same way as the process in step S44 of the second embodiment. The current driving apart 152 receiving the main control signal generated by themain control part 112 energizes themotor 12 based on the main control signal in step S145. In step S146, themain control part 112 determines whether the valve timing is brought to be consistent with the cranking valve timing prior to the time t1. At this moment, themain control part 112 calculates the actual valve timing based on the first rotational speed signal and the second rotational speed signal or on the detected signal by theHall effect elements 18. Then, themain control part 112 executes the above determination by comparing the calculated actual valve timing with the pre-stored cranking valve timing. - When it determines that the valve timing is consistent with the cranking valve timing prior to the time t1, the
main control part 112 executes the maintaining control in step S147. In this maintaining control, the main control signal is generated which is indicative of the control target in order to maintain the cranking valve timing until the time t1 based on the first rotational speed signal and the second rotational speed signal or on the detected signal by theHall effect elements 18 in the case that the first and the second rotational speed signal are not generated. - When it determines that the valve timing is consistent with the cranking valve timing prior to the time t1, an additional control is executed in step S148. In this additional control, the control target is additionally established until the valve timing is consistent with the cranking valve timing based on the detected signals by the Hall effect elements, and the main control signal indicative of the control target is generated.
- After the execution of the process in step S147 or S148, the processes in steps S149 to S151, which corresponds to steps S45 to S47 in the second embodiment, are executed.
- According to the seventh embodiment, the
motor 12 is energized in such a manner that the valve timing at the time t1 is consistent with the cranking valve timing even after the engine shutdown command is generated. In the seventh embodiment, the cranking valve timing may be realized prior to the time t1 or may not be realized even after the time t1 due to disturbances. However, themotor 12 is energized until the engine is completely stopped, so that even if the cranking vale timing is realized prior to the time t1, themotor 12 is energized so as to maintain the cranking valve timing until the time t1. If the cranking valve timing is not realized even at the time t1, themotor 12 is energized until the cranking valve timing is realized. Thus, the engine can be re-started in the condition in which the cranking valve timing is established. - An eighth embodiment is a modification of the seventh embodiment.
FIG. 14 is a flowchart showing the operation of the motor driver. - In
FIG. 14 , step S161 to step S179 are the same processes as step S131 to step S149 in the seventh embodiment. In step S180, themain control part 112 generates and sends the command signal to the powersource control part 114 when the engine is completely stopped and the valve timing is consistent with the cranking valve timing. The powersource control part 114 receiving the command signal generates the first and the second power source control signal in L-level in step S181, so that the power source of the drivingcircuit 150 and themain control part 112 are simultaneously turned off. - According to the eighth embodiment, even after the engine shutoff command is generated, the power source of the driving
circuit 150 and themain control part 112 are turned on, and the drivingcircuit 150 energizes themotor 12 according to the main control signal from themain control part 112. Thereby, the cranking valve timing is maintained in the same manner as the seventh embodiment. The engine can be re-started in the condition in which the cranking valve timing is established. The period in which the power source of the drivingcircuit 150 and themain control part 112 are turned on is substantially equal to the period in which themotor 12 is energized after the engine shutdown command is generated, so that electric power consumption is reduced. - A ninth embodiment is a modification of the first embodiment.
FIG. 15 schematically shows the motor driver according to the ninth embodiment. - In the
motor driver 200, the powersource control part 202 of thecontrol circuit 201 is not connected to the key-sensor 119. As shown inFIG. 16 , when the ignition switch is turned on with the engine off, the powersource control part 202 receiving the signal in H-level from theswitch sensor 118 determines that the engine start command is detected in step S191. Then, in step S192, the powersource control part 202 generates and sends the first and the second power source control signal to themain control part 112. The first and the second power source control signal in H-level cause thecontacts second switch circuit 150 and themain control part 112 are simultaneously tuned on. The power source of the drivingcircuit 150 and the main control part 113 are maintained on until a process in step S203 or the failsafe operation is executed. - The
main control part 112 receiving the command signal from the power source control part starts the engine, and generates the main control signal in step S193 in the same way as step S7 in the first embodiment. Then, the processes in steps S194 to S203 that are the same processes as in steps S8 to S17 of the first embodiment are executed. Thecontrol circuit 110 and theswitch sensor 118 correspond to the detecting means in the present invention. - According to the ninth embodiment, the power
source control part 202 simultaneously controls thefirst switch 130 and thesecond switch 140 to turn on the power source of the drivingcircuit 150 and themain control part 112, so that the control process by thepower source part 202 can be simplified. - FIGS. 17 to 21 shows a valve lift adjuster according to a tenth embodiment. The
valve lift adjuster 300 adjusts a maximum value of an intake valve lift, which is one of the valve characters, using a rotational torque of amotor 320. - The
valve lift adjuster 300 includes anactuator 310 which drive acontrol axis member 330 in an axial direction thereof, and a lift adjusting mechanism (not shown) which adjusts the maximum valve lift amount according to a position of thecontrol axis member 330. The actuator shown inFIG. 7 comprises themotor 320,control axis member 330, atransfer portion 340, a driving cam 350 (shown inFIG. 19 ), anangle sensor 360, and amotor driving apparatus 370. - The
motor 320 is a DC-motor, which comprises arotor 322 on which a coil is wound, and apermanent magnet 324 which covers an outer surface of therotor 322. Amotor gear 328 is provided at an end of amotor shaft 326, which rotates with therotor 322. - The
control axis member 330 is connected to a supportingflame 341 of thetransfer portion 340 at one end thereof, and is connected to a lift adjusting mechanism at the other end thereof. Thecontrol axis member 330 is crossing substantially perpendicularly to themotor shaft 326. As shown inFIGS. 18, 19 , a connectingportion 332, which is one end of thecontrol axis member 330, is engaged with and connected to a connectingportion 342 of the supportingflame 341. Aclip 346 is provided between the connectingportion 332 and the connectingportion 342 to connect both of the connectingportions - The
transfer portion 340 comprises the supportingflame 341 which is square box-shaped, and aroller 344 which is rotatably supported by the supportingflame 341 at an opposite side relative to thecontrol axis member 330. Acamshaft member 352 of the drivingcam 350 is inserted into the inside of the supporting flame 41. The drivingcam 350 has acam surface 353 which is in contact with theroller 344. Acam gear 354 and acam gear 356 are respectively provided at both ends of thecamshaft member 352. Thecam gear 354 engages with themotor gear 328 to form a reduction mechanism. Thecam axis member 352 is disposed in parallel to the motor shat 326. A rotational angle range of thecam gear 354 is restricted is such a manner that two projections (not shown) provided on thegear 354 are brought into contact with engagingmembers - An
angle sensor 360 has asensor gear 362 which engages with thecam gear 356. Theangle sensor 360 detects a rotation angle of a sensor rotation member (not shown) engaging with thesensor 362 with the sensor rotation member and the Hall effect elements. Theangle sensor 360 sends a detected signal to themotor driver 370. - The
motor driver 370 energizes the coil of therotor 322 to drive themotor shaft 326 in normal/reverse direction. - The operation of
valve lift adjuster 300 is described hereinafter. When themotor shaft 326 is rotated, the torque of themotor 320 is transferred to the drivingcam 350 through themotor gear 328 and thecam gear 354. When the drivingcam 350 rotates, contacting with theroller 344, the supportingflame 341 reciprocates in an axial direction of theaxis member 330. The valve lift adjusting mechanism adjusts the maximum valve lift according to the position of theaxis member 330, which moves along the cam profile of thecam surface 353 of theriving cam 350. - The
motor driver 370 has the almost same structure as themotor driver 100 of the first embodiment except following structure. The same parts and components as those in themotor driver 100 are indicated with the same reference and the same descriptions will not be reiterated. - Referring to
FIG. 20 , themain control part 374 of thecontrol circuit 372 establishes the control target to drive themotor 320 in order to realize the maximum valve lift amount which is suitable to the current engine condition. Themain control part 374 receives a detected signal from theangle sensor 360. - The
current driving part 382 of the drivingcircuit 380, as shown inFIG. 21 , has abridge circuit 386 which eliminated one row of thearms 155 from thebridge circuit 156 of the first embodiment. Thecurrent driving part 382 receives a detected signal from theangle sensor 360 which is connected thereto. Thecurrent driving part 382 establishes a switching pattern and turns on/off the switchingelements motor 320, so that the control target represented by the main control signal is realized. - The
motor driver 370 conducts almost the same operation as the first embodiment. Themain control part 374 establishes the control target based on the detected signal by theangle sensor 360 in order to realize the cranking valve lift that is a maximum valve lift required at the engine starting in step corresponding to step S3 of the first embodiment. Thecurrent driving part 382 executes step corresponding to step S4, so that the maximum valve lift amount is consistent with the cranking valve lift amount. In step corresponding to step S7, themain control part 374 establishes the control target based on the detected signal by theangle sensor 360 in order to realize the after-start valve lift amount which is the maximum valve lift amount required after the engine is turned on. Thecurrent driving part 382 executes step corresponding to step S8 to cause the maximum valve lift amount to be consistent with the after-start valve lift amount. In step corresponding to step S10, themain control part 374 establishes the control target based on the first and the second rotational speed signal in order to realize the suitable maximum valve lift amount. Thecurrent driving part 382 executes step corresponding to step S11 to hold or change the maximum valve lift amount to the suitable amount for the engine. In step corresponding to step S14, themain control part 374 established the control target to realize the cranking valve lift amount based on the first and the second rotational speed signal or a detected signal by theangle sensor 360 in the case that the rotational speed signals are not generated. Thecurrent driving part 382 executes step corresponding to step S15, whereby the maximum valve lift is brought into be consistent with the cranking valve lift amount and be kept. - The
motor driver 370 conducts the same failsafe operation as the first embodiment. - In the tenth embodiment, the
control circuit 372, thefirst switch 130, and thesecond switch 140 correspond to a power source control means. Thecontrol circuit 372, theswitch sensor 118 and the key-sensor 119 correspond to a detecting means of the present invention. - According to the tenth embodiment, when the insert operation of the ignition key is detected before the engine start command is generated, the power source of the driving
circuit 380 and themain control circuit 374 are turned on to energize themotor 320. Thereby, the maximum valve lift amount is kept in the cranking valve lift amount, so that the cranking valve lift amount is realized at the time of stating the engine. - When the engine-start command is detected, the driving
circuit 380 energizes themotor 320 according to the main control signal which is generated without respect to the first and the second rotational speed signal even before the first and the second rotational speed signal are generated. Thereby, the after-start valve lift amount is continuously maintained until the first and the second rotational speed signal are detected. - When the engine shutdown signal is detected, the power source of the driving
circuit 380 and themain control part 374 are turned on until the period T2 has passed in order to drive themotor 320 until the period T1 has passed. Thereby, the maximum valve lift amount can be consistent with the cranking valve lift amount at the time when the engine is completely stopped, so that the engine can be re-started in the condition in which the cranking valve lift amount is established. Furthermore, when the over-current is passed through the drivingcircuit 380 and themotor 320 under the normal operation, the failsafe operation is executed to turn off the power source of the drivingcircuit 380, so that the malfunction of the drivingcircuit 380 and themotor 320 can be avoided. - [Modification]
- In the first to tenth embodiments, the non-contact relay comprised of a semiconductor circuit can be used as the first and the
second switch source control part 114 can generate the fist and the second power source signal in H-level to turn on the power source of the drivingcircuit 150 and themain control part 112 based on a braking operation by a driver, an operation of fastening a seatbelt, or stepping operation of a clutch by the driver instead of the insert operation of the ignition key. In this case, a sensor detecting the operation above is connected to thepower source part main control part circuit source control part 202 can generates the first power source control signal in L-level and the second power source signal in H-level, so that the power source of themain control part 112 can be turned on prior to the power source of the drivingcircuit 150. In the first to the tenth embodiment, the engine can be replaced by a hybrid engine. The three-phase motor can be replaced by the other known motor. - In the first embodiment, step S12 to step S17 can be skipped. In the ninth embodiment, step S192, step S193, and step S194 can be skipped. In this case, the
motor 12 is energized when the rotational speed of the crankshaft and the camshaft become under the lowest value detected by the first and the secondrotational speed sensor - In the tenth embodiment, the valve lift amount can be adjusted with respect to the exhaust valve. Steps corresponding to steps S12 to S17 can be skipped. The normal operation that is same as in the second to ninth embodiments can be executed by the
motor driver 370. When the operation corresponding to that of the second and the third embodiment is executed, themain control part 374 establishes the control target to realize the cranking valve lift amount at the time t1 in step corresponding to step S44 or step S64. When the operation corresponding to that of the fourth, the fifth, or the sixth embodiment is executed, themain control part 374 calculates the control target in such a manner that the cranking valve lift amount is realized at the time t1. In the tenth embodiment, when the operation corresponding to that of the seventh or eighth embodiment is executed, themain control part 374 establishes the control target, and determines whether the maximum valve lift amount is consistent with the cranking valve lift amount in step corresponding to step S146 or S176. In the tenth embodiment, the operation corresponding to that of the seventh or eighth embodiment is executed, themain control part 374 establishes the control target in step corresponding to step S147 or S177, and in step corresponding to S148 or S178 themain control part 374 establishes the control target. In the tenth embodiment, when the operation corresponding to that of the eighth embodiment is executed, themain control part 374 generates and sends the command signal to thepower control part 114.
Claims (34)
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JP2004-128268 | 2004-04-23 | ||
JP2004128268A JP4647934B2 (en) | 2004-04-23 | 2004-04-23 | Valve characteristic adjustment device |
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US20050235938A1 true US20050235938A1 (en) | 2005-10-27 |
US7252055B2 US7252055B2 (en) | 2007-08-07 |
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US11/111,780 Active US7252055B2 (en) | 2004-04-23 | 2005-04-22 | Valve controller |
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JP (1) | JP4647934B2 (en) |
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JP2982604B2 (en) * | 1994-02-23 | 1999-11-29 | トヨタ自動車株式会社 | Valve timing control device for internal combustion engine |
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WO2007142322A1 (en) | 2006-06-09 | 2007-12-13 | Toyota Jidosha Kabushiki Kaisha | Variable valve timing apparatus and control method thereof |
US20100235067A1 (en) * | 2006-06-09 | 2010-09-16 | Toyota Jidosha Kabushiki Kaisha | Variable valve timing apparatus and control method thereof |
US8180552B2 (en) | 2006-06-09 | 2012-05-15 | Toyota Jidosha Kabushiki Kaisha | Variable valve timing apparatus and control method thereof |
EP2151549A4 (en) * | 2007-06-04 | 2016-03-09 | Denso Corp | Valve timing adjustment device |
US20130297138A1 (en) * | 2010-12-22 | 2013-11-07 | Toyota Jidosha Kabushiki Kaisha | Vehicle, method for controlling vehicle, and device for controlling vehicle |
US8843262B2 (en) * | 2010-12-22 | 2014-09-23 | Toyota Jidosha Kabushiki Kaisha | Vehicle, method for controlling vehicle, and device for controlling vehicle |
US9243569B2 (en) * | 2012-04-04 | 2016-01-26 | Ford Global Technologies, Llc | Variable cam timing control during engine shut-down and start-up |
US20130268179A1 (en) * | 2012-04-04 | 2013-10-10 | Ford Global Technologies, Llc | Variable cam timing control during engine shut-down and start-up |
US10316765B2 (en) | 2012-11-29 | 2019-06-11 | Toyota Jidosha Kabushiki Kaisha | Control device and control method for internal combustion engine |
US11428172B2 (en) * | 2020-07-01 | 2022-08-30 | Aisin Corporation | Valve opening and closing timing control device |
US20220145784A1 (en) * | 2020-11-12 | 2022-05-12 | Schaeffler Technologies AG & Co. KG | Camshaft phaser with trigger wheel including magnetic material |
US11891925B2 (en) * | 2020-11-12 | 2024-02-06 | Schaeffler Technologies AG & Co. KG | Camshaft phaser with trigger wheel including magnetic material |
US20220364485A1 (en) * | 2021-05-13 | 2022-11-17 | Borgwarner Inc. | Method for controlling camshaft orientation for improved engine re-starting of an engine having start-stop capability |
US11643950B2 (en) * | 2021-05-13 | 2023-05-09 | Borgwarner Inc. | Method for controlling camshaft orientation for improved engine re-starting of an engine having start-stop capability |
Also Published As
Publication number | Publication date |
---|---|
DE102005018739B4 (en) | 2017-01-05 |
DE102005018739A1 (en) | 2005-12-29 |
US7252055B2 (en) | 2007-08-07 |
JP4647934B2 (en) | 2011-03-09 |
JP2005307910A (en) | 2005-11-04 |
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